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Perfluoroalkyl acids inhibit reductive dechlorination of trichloroethene by repressing Dehalococcoides Tess S. Weathers, Katie C. Harding-Marjanovic, Christopher P. Higgins, Lisa Alvarez-Cohen, and Jonathan O. Sharp Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.5b04854 • Publication Date (Web): 04 Dec 2015 Downloaded from http://pubs.acs.org on December 10, 2015
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Perfluoroalkyl acids inhibit reductive dechlorination
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of trichloroethene by repressing Dehalococcoides
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Tess S. Weathers,1 Katie Harding-Marjanovic,2 Christopher P. Higgins,1 Lisa Alvarez-Cohen,2
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Jonathan O. Sharp1*
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1
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Engineering, Colorado School of Mines, Golden, CO 80401
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KEYWORDS. Poly- and perfluoroalkyl substances; Microbiology; Dehalococcoides; reductive
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dechlorination; PFOS; PFOA; AFFF
Hydrologic Science and Engineering Program and Department of Civil and Environmental
Civil and Environmental Engineering, University of California Berkeley, Berkeley, CA 94720
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ABSTRACT. The subsurface recalcitrance of perfluoroalkyl acids (PFAAs) used in aqueous
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film-forming foams could have adverse impacts on microbiological processes used for the
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bioremediation of comingled chlorinated solvents such as trichloroethene (TCE). Here we show
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that reductive dechlorination by a methanogenic, mixed culture was significantly inhibited when
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exposed to concentrations representative of PFAA source zones (>66 mg/L total of 11 PFAA
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analytes, 6 mg/L each). TCE dechlorination, cis-dichloroethene, and vinyl chloride production
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and dechlorination, and ethene generation were all inhibited at these PFAA concentrations.
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Phylogenetic analysis revealed that the abundances of 65% of the operational taxonomic units
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(OTUs) changed significantly when grown in the presence of PFAAs, although repression and/or
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enhancement resulting from PFAA exposure did not correlate with putative function or
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phylogeny. Notably, there was significant repression of Dehalococcoides (8-fold decrease in
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abundance) coupled with a corresponding enhancement of methane-generating Archaea (a 9-fold
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increase). Growth and dechlorination by axenic cultures of Dehalococcoides mccartyi strain 195
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were similarly repressed under these conditions, confirming an inhibitory response of this pivotal
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genus to PFAA presence. These results suggest that chlorinated solvent bioattenuation rates
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could be impeded in subsurface environments near PFAA source zones.
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INTRODUCTION. Poly- and perfluoroalkyl substances (PFASs) are contaminants of
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emerging concern found throughout the environment.1 PFASs are used in a diverse range of
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industrial, consumer, and commercial applications including pesticides, non-stick coatings, and
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in fire-fighting foams.1–3 These compounds are environmentally recalcitrant, exhibit toxicity
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effects in primates and microbiota, and can bioaccumulate.4–8 The prevalent use and
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environmental longevity, coupled with improvements in quantification, have led to widespread
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environmental detection in groundwater, surface water, soil, and air, as well as detection in
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humans, wildlife, and food crops.6,9–11 The U.S. Environmental Protection Agency has set
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provisional drinking water health advisories for two common PFASs: 0.4 µg/L for
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perfluorooctanoate (PFOA) and 0.2 µg/L for perfluorooctanesulfonate (PFOS).2
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Perfluoroalkyl acids (PFAAs), a subset of PFASs, are present in and can arise from
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components of aqueous film-forming foams (AFFF) used for fuel fire suppression.12 Use of
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AFFF for military firefighter training has led to the introduction of PFAAs into groundwater in
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sites that are often contaminated with chlorinated solvents3,13–15 such as trichloroethene (TCE)
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and its toxic daughter products cis-dichloroethene (cDCE) and vinyl chloride (VC).16 Enhanced
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reductive dechlorination (ERD) is a bioremediation process for chlorinated solvents in which an
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electron donor, such as lactate (biostimulation), or potentially a known microbial consortium
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containing Dehalococcoides (bioaugmentation) is supplied.16 Members of the genus
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Dehalococcoides are known to completely degrade tetrachloroethene (PCE) and TCE to ethene,
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thus limiting the potential for toxic accumulation of vinyl chloride.17 Dehalococcoides have been
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incorporated into ERD consortia in laboratory settings17–19 and are often found in aquifers
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wherein complete PCE and TCE dechlorination has been observed.20,21 It is yet unknown how
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PFAAs may impact microbial communities relevant to chlorinated solvent bioremediation.
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While biodegradation of PFAAs is not expected,2 there are concerns regarding potential adverse
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effects from PFAA exposure on subsurface microbial communities and co-contaminant
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degradability.1 Biodegradation of another commonly co-located contaminant, toluene, was not
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impacted in pure culture studies, however the presence of PFAAs did correlate to increased
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formation of extracellular polysaccharides and enhanced transcription of stress-related genes.7
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Consequently, unanticipated impacts on PFAA or chlorinated solvent fate and transport in
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groundwater sources are possible, ranging from effects on co-contaminant degradation and
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microbial processes, to changes in sorptive properties of PFAAs as a result of biostimulation or
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bioaugmentation.
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The objective of this study was to assess potential impacts of these nontraditional
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contaminants, PFAAs, on reductive dechlorination of TCE. This was accomplished by querying
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for suppression of reductive dechlorination activity by a Dehalococcoides-containing
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methanogenic mixed community cultivated in the presence of varied concentrations of PFAAs.
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In parallel, we contrasted the community structure and putative functionality of these
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microcosms to understand ecological shifts and metabolic redundancy within this consortium
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that could be attributed to PFAA presence. Insights from the ecological profiles were then used
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to challenge an axenic culture of Dehalococcoides with PFAAs to understand the direct impact
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on this bacterial genus. Results revealed suppression of Dehalococcoides growth and reductive
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dechlorination rates in both pure culture and mixed assemblages.
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MATERIALS AND METHODS. PFAA preparation and aqueous analysis. Purity corrected
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stock solutions of an eleven-analyte mixture were prepared as described elsewhere.7,14 PFAA
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salts (Sigma Aldrich) were suspended in a 70/30 (v/v) methanol/water solution. Water used in
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this study was generated with a Milli-Q system (Millipore). Unless otherwise specified, each
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mixture
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perfluoroheptanoate, PFOA, perfluorononanoate, perfluorodecanoate, perfluoroundecanoate,
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perfluorobutanesulfonate, perfluorohexanesulfonate, and PFOS. These compounds represent a
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range of carbon chain lengths and are commonly found at AFFF-impacted sites.1,11,22 Empty
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culture bottles were spiked with the PFAA mixture while in an anaerobic chamber (90%
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nitrogen, 5% hydrogen, 5% carbon dioxide) and the methanol was evaporated as described
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elsewhere.7 Final PFAA concentrations were verified using liquid chromatography tandem mass
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spectroscopy with stable-isotope surrogate standards (Wellington Laboratories). Aqueous
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samples were centrifuged to remove particulates, sampled, and diluted as appropriate. A SCIEX
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3200 mass spectrometer (MDS Sciex) was utilized with MultiQuant for quantitation to verify
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PFAA recovery.7
contained
perfluorobutanoate,
perfluoropentanoate,
perfluorohexanoate,
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Cellular preparation. Anaerobic experiments were inoculated with a Dehalococcoides-
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containing methanogenic mixed culture that was maintained in a stock bottle amended with
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exogenous cobalamin co-factors, such as vitamin B12, to enable TCE dechlorination.19,23 This
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stable and robust culture maintained in Berkeley, CA was derived from TCE-contaminated
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groundwater.23 The Dehalococcoides strains in this culture are most similar to Dehalococcoides
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mccartyi strain 195.23 The described culture ferments lactate to produce hydrogen and acetate,
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the necessary electron donor and carbon source for Dehalococcoides. Pure culture experiments
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using Dehalococcoides mccartyi strain 195 were maintained under similar conditions as the
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mixed culture, but were amended with acetate and hydrogen instead of lactate.17
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Reductive dechlorination with the mixed culture. Batch systems containing TCE, lactate, and a
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PFAA mixture were designed to evaluate microbial degradation rates. ERD experiments
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contained triplicate sets of 22, 66, or 110 mg/L total PFAAs added to sterile 60 mL serum bottles
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as well as 0 mg/L controls spiked with non-PFAA containing 70/30 v/v methanol/water. These
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concentrations were chosen to reflect what may be observed near a PFAA source zone3 (110
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mg/L total at 10 mg/L each of 11 analytes) and to determine if there is a PFAA concentration
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threshold wherein biological effects are not observed. Following PFAA addition and methanol
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evaporation described in the prior section, bottles were sealed with butyl rubber stoppers. Next,
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48.5 mL of an autoclaved mineral salts medium24 containing 20 mM lactate as electron donor
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and 100 µg/L vitamin B12 was added to stoppered bottles with a sterile syringe. During media
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addition, an exhaust needle was inserted into the stopper to avoid bottle pressurization, while low
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flow rates were used to minimize PFAA volatilization and flushing. After media addition, the
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headspace was gently flushed with N2/CO2 (90:10) to remove residual hydrogen and oxygen.
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Each bottle was then amended with approximately 20 µmoles of TCE (Sigma Aldrich, 99.9%)
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and allowed to sit for at least 24 hours to facilitate TCE and PFAA equilibration. At time zero,
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the bottles were inoculated with 3% (v/v) of the previously-grown methanogenic mixed
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community stock culture and incubated in the dark at 34ºC for the duration of the experiment.
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All bottles were inverted several times at each sampling point to promote PFAA mixing. Abiotic
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controls devoid of microorganisms were prepared for the parallel pure-culture experiment. After
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TCE dechlorination profiles were generated, the bottles were sampled for phylogenetic
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sequencing and verification of PFAA concentrations.
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Dechlorination measurements. Chloroethenes, ethene, and methane were measured by
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injecting 100 µL of culture headspace into an Agilent 7890A gas chromatograph equipped with a
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flame ionization detector and 30 m x 0.32 mm J&W capillary column (Agilent Technologies).
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Hydrogen concentrations were measured by injecting diluted headspace samples into a gas
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chromatograph fitted with a reductive gas detector (Trace Analytical). Between 50 and 300 µL of
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culture headspace was withdrawn for each hydrogen measurement and diluted in 17 mL glass
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vials purged with N2 to generate concentrations within the linear calibration range of the
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instrument. The total volume of extracted headspace was tracked throughout the incubation to
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ensure that the same approximate volume was removed from all bottles (1.5 to 1.9 mL). Initial
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TCE dechlorination rates were determined by obtaining the slope of a time-course regression
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through the linear portion of the degradation curve (days 1 through 4) after accounting for loss as
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a function of time generated from the abiotic control. Production rates for cDCE, VC, and ethene
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were also tabulated during the linear portion of the generation curve for each sample.
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Phylogenetic sequencing. Every sample containing the methanogenic mixed culture was
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extracted after dechlorination profiles were complete (~8 days). DNA was extracted with the
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PowerSoil DNA Isolation Kit (MO BIO Laboratories, Inc.). Extracted DNA was quantified with
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a Qubit 2.0 Fluorometer and dsDNA HS Assay Kit (Life Technologies). Each sample was
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amplified using a TC-412 Thermocycler (TECHNE) with 2 µL DNA template, 2 µL each
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forward and reverse primers at 10 µM each, 6.5 µL PCR grade water, and 12 µL Phusion 2×
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MasterMix (New England BioLabs, Inc.). Dual-indexed primers (515F and 805R) target the V4
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region of the 16s rRNA gene (Integrated DNA Technologies) and are described in the SI along
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with the amplification protocol. Select samples were run via gel electrophoresis to confirm
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amplicons of a desired length of roughly 300 base pairs. Samples were purified and normalized
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with the SequalPrep Normalization Kit (Invitrogen) according to the manufacturer’s protocol and
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pooled into a 2 mL RNAse and DNAse free sterile microcentrifuge tube. Pooled samples were
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concentrated with µltra-.05 30K Centrifugal Filter Devices (Amicon) according to the provided
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protocol. Pooled samples were quantified using the Qubit Fluorometer as described above and
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diluted and re-quantified if necessary to normalize concentrations. Half of the final pooled
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sample volume was archived at -80°C with the balance sent for MiSeq sequencing using the V2
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250 Cycle Paired-End kit at BioFrontiers Institute (Boulder, CO).
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Sequence post-processing was performed with MacQIIME version 1.9.025 with OTU picking
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and chimera screening using Usearch6126,27 and alignment with PyNAST.28,29 Taxonomy was
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assigned with Greengenes reference database version 12_1030 using RDP Classifier 2.2.31
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FastTree 2.1.3 was used to generate the phylogenetic tree32 and was further manipulated in
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FigTree.33 Weighted, non-rarefied beta diversity was visualized with EMPeror,34 and adonis and
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ANOSIM test statistics were calculated using compare categories.35 Samples were filtered so the
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minimum total observed fraction per OTU was 0.001. Taxa were summarized such that the OTU
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identifier with the greatest total abundance was retained: if the lowest classification for multiple
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OTU identifiers resulted in the same taxonomic assignment, the specific OTU identifier with the
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greatest total abundance was retained. The abundance of the resulting merged OTU reflects the
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sum of each OTU with the same taxonomic lineage. Differential abundances were calculated
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with the DeSeq2 package; the adjusted p values are reported herein.36 The relative abundances
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represent the average ± standard deviation between the three experimental replicates per
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condition. Reporting of results and analysis within this work reflects the lowest identified
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taxonomic level of each OTU.
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Functionality was assigned based on the class level information for the non-dechlorinating
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members of the consortium according to the comparative metagenomics study performed by Hug
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et al.19 The methanogenic mixed culture used herein is similar to the ANAS culture maintained
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in Berkeley, California described in Hug et al.18,19 which also uses lactate as an electron
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donor.18,37 The functions discussed by Hug et al.19 have been applied to the culture within this
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study. Sequence data have been submitted to the National Center for Biotechnology Information
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Sequence Read Archive database (accession numbers pending). Post-processing scripts can be
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found in the SI.
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RESULTS AND DISCUSSION. Effect of PFAAs on reductive dechlorination by a mixed
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culture. Batch microbial incubations across a range of PFAA concentrations revealed that TCE
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dechlorination was severely inhibited when the methanogenic mixed culture was grown in the
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presence of 110 mg/L PFAA (Figure 1). This corresponded with reduced cDCE production as
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well as limited VC and ethene production. Inhibition effects on TCE dechlorination were also
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observed at 66 mg/L manifested by a decrease in dechlorination rates of TCE as compared to the
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case without PFAAs (p
